ELS3101 Elektronika II

Kode Matakuliah:

ELS3101

Bobot sks:

3

Semester:

5

KK / Unit Penanggung Jawab:

Prodi S1 Teknik Elektro

Sifat:

Wajib

Nama Matakuliah Elektronika II
Electronics II
Silabus Ringkas Analisis dan desain rangkaian elektronik. Amplifier rangkaian terpadu: blok bangunan, diferensial dan tahap ganda, umpan balik, rangkaian opamp. Filter dan tuned-amplifier. Rangkaian untuk pembangkitan sinyal, regulasi tegangan, elemen penyimpanan digital.
Analysis and design of electronic circuits. Integrated-circuits amplifiers: building blocks, differential and multi stage, feedback, opamp circuits. Filter and tuned amplifiers. Circuits for signal generation, voltage regulation, digital storage elements.
Silabus Lengkap Mata kuliah ini adalah kuliah lanjutan dalam analisis dan desain rangkaian elektronika. Kuliah ini mencakup penguat diferensial dan multi tahap, penguat umpan balik, blok bangunan dan rangkaian untuk perancangan opamp, filter dan tuned-amplifier, pembangkitan sinyal: osilator dan rangkaian pembentuk gelombang, regulasi tegangan: linear dan switched-mode, rangkaian untuk elemen sirkuit digital. Setelah mengikuti kuliah ini mahasiswa diharapkan mampu mengidentifikasi, menganalisis, mendiskusikan, dan desain blok pembangun dan rangkaian terintegrasi untuk penguat operasional, mengidentifikasi dan menggunakan rangkaian filter, osilator, regulator dan rangkaian analog pendukung elemen meori digital.
This course is an intermediate course in electronic circuit analysis and design. It covers differential and multi stage amplifiers, feedback amplifiers,building blocks and circuits for opamp design, filter and tuned amplifiers, signal generation: oscillators and wave shaping circuits, voltage regulation: linear and switch-mode, circuits for digital circuit elements. Finishing this course student will be able to identify, analyze, discuss, and design building blocks and circuits for integrated circuit amplifiers. Identify and apply filters and tuned amplifiers, oscillators, and voltage regulators circuits, and analog circuits for digital circuit elements.
Luaran (Outcomes)
  1. Understand the rationale for a differential and multi stage amplifiers, and design one to specifications.
  2. List the benefits of negative feedback for amplifier circuits, identify, the type of feedback at work in a given amplifier circuit, and estimate the feedback factor, loop gain, and the allied properties, and Determine, using simulation or by analysis, the phase margin for a given feedback amplifier circuit.
  3. Design an RC, LC, or crystal oscillators for a given frequency and for a desired output waveform and design a digital clock generator.
  4. Identify, analyse and design filters and tuned-amplifiers.
  5. Identify and calculate performance parameters of a voltage regulator, design simple series and shunt regulator, and apply IC voltage regulators.
  6. Identify, analyse, and discuss properties of analog circuits for memory elements.
Matakuliah Terkait ELS2202 Elektronika I Prasyarat
ELS2203 Praktikum Elektronika II Bersamaan
Kegiatan Penunjang  
Pustaka
  1. Sedra and K. Smith, Microelectronic Circuits International 6th ed., Oxford University Press, 2011
Thomas L Floyd, Electronic Devices 9th ed, Prentice Hall, 2011
 
Panduan Penilaian [Termasuk jenis dan bentuk penilaian]
Catatan Tambahan  
Mg# Topik Sub Topik Capaian Belajar Mahasiswa Sumber Materi
1
  • Building Blocks of amplifiers (3)
  • Gain cell
  • Cascode amplifier
  • Bias circuits
  • Identify building block of amplifiers
  • Analyze and discuss their properties
  • Design building blocks to meet stated specification
Sedra Chp. 6.
Sec. 6.1 – 6.6
2
  • Differential Amplifiers (3)
  • MOS differential pair
  • Small signal operation of MOS differential pair
  • BJT Differential pair
  • Use large signal and incremental LEC device models to analyze differential pairs.
  • Explain, compare, and contrast the input, output, and gain characteristics of differential pairs as amplifiers.
Sedra Chp. 7.
Sec. 7.1 – 7.3
3
  • Differential Amplifiers (3)
  • Nonideal characteristics
  • Differential with active load
  • High frequency response of differential amplifier
  • Use large signal and incremental LEC device models to analyze nonideal characteristics of differential pairs.
  • Explain, compare, and contrast the input, output, and gain characteristics of differential pairs with active loads.
  • Produce and analyse the small signal high frequency BJT and MOSFET models differential amplifier circuits.
Sedra Chp. 7.
Sec. 7.4 – 7.5

Sedra Chp. 8
Sec. 8.8

 

4
  • Multistage Amplifiers (3)
  • Two-stage CMOS opamps
  • A bipolar opamp
  • Wide band amplifiera and multistage frequency response
  • Explain, compare, and contrast the characteristics of common two-transistor linear amplifier building block stages.
  • Produce and analyse the small signal high frequency multistage amplifier circuits.
Sedra Chp. 7
Sec. 7.6

Sedra Chp. 8
Sec. 8.9-8.10

5
  • Feedback (3)
  • Feedback structures and properties of negative feedback.
  • Feedback topologies: shunt-series, shunt-shut, series-series, series-shunt.
  • Two-port modelling and the small signal analyses of feedback amplifier.
  • Explain the benefits of negative feedback.
  • Distinguish the feedback circuits and the different feedback configurations in feedback amplifiers. (C2)
  • Apply the two-port models to include the loading effect of a feedback circuit to the main amplifier. (C3)
Sedra Chp. 9
Sec. 9.1-9.3

 

6
  • Feedback (3)
  • Analyses of feedback amplifiers.
  • Analyse frequency response of feedback amplifiers. (C4)
Sedra Chp. 9
Sec. 9.4-9.7
7
  • Feedback (3)
  • Loop gain and amplifier stability.
  • Stability analyses
  • Frequency compensation
  • Survey the stability of feedback amplifiers.
  • Design amplifier frequency compensation.
Sedra Chp. 9
Sec. 9.10-9.13

 

8
  • Operational Amplifier circuits (3)
  • Two-stage Opamp.
  • Folded Cascode Amplifiers.
  • Analyses of 741 Opamp: DC bias
  • Point out what components in a circuit affect the low frequency, midband, and high frequency responses, and compute the frequency response for circuits including multiple low and high frequency poles/zeroes.
  • Analyse CMOS Operational Amplifier.
  • Subdivide a large analog circuits io its simple building blocks.
  • Analyse DC bias circuit of 741 opamp.
Sedra Chp. 10
Sec. 10.1-10.4

 

9
  • Operational Amplifier circuits (3)
  • Analyses of 741 Opamp: small-signal
  • Analyses of 741 Opamp: Gain, Frequency Response and Slew rate
  • Modern BJT opamps
  • Produce the small signal equivalent circuits of 741 opamp.
  • Analyse the performance of 741 opamp.
  • Describe niches in modern opamp designs.
Sedra Chp. 10
Sec. 10.5-10.7

 

10
  • Filter and Tuned Amplifier
  • Filter specification, approximation, and transfer function
  • Filter topologies and implementations.
  • Switched-capacitor Filters
  • Tuned amplifier
  • Draw the frequency response curves of a low-pass active filter, a high-pass active filter, a band-pass active filter, and a band-stop ( notch ) filter
  • Construct, analyze, and troubleshoot an active low-pass filter, an active high-pass filter, a band-pass filter, or a band-stop ( notch ) filter.
  • Identify SC Filter.
  • Compare the frequency response characteristics of an ideal amplifier and a practical tuned amplifier. (C4)
  • Perform analyses to calculate the Q and bandwidth of an amplifier. (C4)
Sedra Chp. 11
Sec. 11.1-11.2

Sec. 11.10-11.11

 

11
  • Signal Generators (Oscillators) and Waveform-shaping Circuits
  • Principles of sinusoidal oscillators: Barkhausen Criterion and Negative Resistance.
  • Opamp-RC oscillators
  • LC, and Crystal oscillators.
  • Describe the function and requirements of an oscillator. (C2)
  • Describe positive feedback, how it is produced, and how it maintains oscillations after an oscillator is triggered, and list requirements for proper oscillator operation. (C2)
  • Identify, draw the circuits and calculate the parameters for opamp-RC crystal oscillator circuits.  (C3)
Sedra Chp. 12
Sec. 12.1-12.3

 

12
  • Signal Generators (Oscillators) and Waveform-shaping Circuits
  • Multivibrators and IC timers
  • Waveform-shaping circuits.
  • Identify, draw the circuits and calculate the parameters for LC , and crystal oscillator circuits.  (C3)
  • Analyze different types of oscillators used in common electronics. (C4)
  • Analyse and understand the operation of wave shaping circuits. (C4)
Sedra Chp. 12
Sec. 12.4-12.9

 

13
  • Voltage and current regulations
  • Shunt and series linear continuous voltage regulator circuits.
  • Voltage regulator circuits with monolithic integrated circuits.
  • List the purpose of a voltage regulator and Explain concept of regulation and methods for regulating voltage and current. (C2)
  • Calculate performance parameters of a voltage regulator, such as line regulation and load regulation. (C3)
  • Apply IC linear voltage regulator circuits to design specified output voltage levels. (C3)
Floyd Chp. 17
14
  • Voltage and current regulations
  • Swicthed-mode regulation: Buck and Boost configurations.
  • Describe the circuit operation of a buck/boost switching voltage regulator. (C2)
  • Apply IC switched regulator sicyuits to design a simple buck/boost switching voltage regulator. (C3)
Floyd Chp. 17
15
  • Circuits for digital storage elements (3)
  • Latches and Flipflop. Multivibrator circuits.
  • Semiconductor memory types: RAM, ROM, and Flash.
  • Memories address: and sensing amplifiers, row decoder, column decoder.
  • Describe the structure, configuration, timing parameters and diagrams for memory elements. (C2)
  • Explain and show the operation of latch circuit and flip-flop circuits and mutivibrators: bistable, monostable, astable. C(3)
  • Explain the operation and analyses of different types of memories. (C2)
  • Explain the operation of memory addressing circuits: sensing amplifiers, row decoder, column decoder. (C2)
Sedra Chp. 16
Sec. 16.1-12.4